Spatial and Temporal Variation, Simulation and Prediction of Land Use in Ecological Conservation Area of Western Beijing
Abstract
:1. Introduction
2. Materials and Methods
2.1. Study Area
2.2. Data Source and Processing
2.3. Methods
2.3.1. Technical Pathway
2.3.2. Driving Factors
2.3.3. Landscape Pattern Indices
2.3.4. PLUS Model
2.3.5. FLUS Model
2.3.6. Markov Model
3. Results
3.1. The Overall Characteristics of Land Use in Western ECA of Beijing
3.2. Temporal and Spatial Variation of Land Use
3.3. Land-Use Landscape Pattern Change Analysis
3.4. Comparison and Accuracy Evaluation of Simulation Results
3.5. Prediction
4. Discussion
- Restrict new construction land and enhance land use economically. The expansion of construction land in the ECA in western Beijing is potentially insufficiently regulated, resulting in a chaotic spatial distribution that can have greater negative implications on the landscape. Therefore, in the next development plan, controls may be needed to limit the increase in construction land and improve the utilization rate of land resources. At the same time, existing construction land resources in the western suburbs of Beijing could be optimized to reduce damage caused by new construction to the environment.
- Stick to the red line of cultivated land (a cultivated land protection system in China) and protect cultivated land resources. While urbanization is developing and building area is increasing, it also decreases the area of cultivated land around the city. Cultivated land is an important land resource that satisfies people’s most basic food, clothing, housing and transportation needs. The loss of cultivated land will hinder social and economic development. When planning the future land use in the ECA of western Beijing, we must pay attention to protecting the basic status of cultivated land and strictly control the further reduction of cultivated land.
- Increase stakeholder knowledge and innovate suitable sustainable local land-use patterns.
- Control land prices reasonably.
5. Conclusions
- Forest is the main land-use type in this area, accounting for more than half of the area. In contrast, the proportion of water is the smallest. The area of construction land in the study area continued to increase from 2000 to 2020. The landscape is becoming more and more diversified; however, patch connectivity is good, but the landscape fragmentation of water and grassland is increasing from 2000 to 2020.
- When simulating the land-use conditions in the study area, the PLUS model is better than the FLUS model in terms of the numerical accuracy of the simulation results, the quantitative comparison of landscapes and the spatial accuracy.
- The prediction results show that construction land will continue to increase in 2030, forest and cultivated land will continue to decrease and government policies can play a role in land-use changes.
- There is an unsustainable land-use pattern in the ECA of western Beijing, which needs to be adjusted as soon as possible, otherwise it will affect the ecological environment.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Land Type Number | Land Type Name | Description |
---|---|---|
1 | Grassland | Land types with surface coverage above 10% are mainly natural herbaceous vegetation, such as grassland, meadow and artificial grassland constructed by urban greening. |
2 | Forest | Forest land mainly refers to the land surface covered by trees and shrubs. In the ECA of western Beijing, the coverage of tree crown and shrub is more than 30%. Common tree types include deciduous broad-leaved forest, deciduous coniferous forest, evergreen coniferous forest and mixed forest. Shrub types include mountain shrub, deciduous and evergreen shrub. |
3 | Water | The area covered by liquid water as is displayed on satellite images, such as rivers and lakes. |
4 | Construction land | Human beings need to build artificial surfaces to meet the needs of living space and economic development. Common urban residential areas, villages, industrial and mining production land, traffic land, etc. |
5 | Cultivated land | Land used by rural residents to farm a variety of food crops and cash crops, such as irrigated drylands, vegetable greenhouses and land that grows fruit trees or other economically valuable trees. |
Land-Use Type | Grassland | Forest | Water | Construction Land | Cultivated Land |
---|---|---|---|---|---|
Grassland | 1 | 1 | 0 | 0 | 1 |
Forest | 1 | 1 | 0 | 0 | 1 |
Water | 1 | 1 | 1 | 0 | 1 |
Construction land | 1 | 1 | 0 | 1 | 1 |
Cultivated land | 1 | 1 | 0 | 0 | 1 |
Land-Use Type | Grassland | Forest | Water | Construction Land | Cultivated Land |
---|---|---|---|---|---|
Neighborhood weight | 0.5 | 0.7 | 0.1 | 0.1 | 0.1 |
Land-Use Type | 2000 | 2010 | 2020 | |||
---|---|---|---|---|---|---|
Area/hm2 | Proportion/% | Area/hm2 | Proportion/% | Area/hm2 | Proportion/% | |
Grassland | 49,913.55 | 9.69 | 37,644.30 | 7.30 | 37,845.81 | 7.35 |
Forest | 346,655.25 | 67.26 | 346,481.01 | 67.23 | 348,170.04 | 67.58 |
Water | 2426.85 | 0.47 | 1088.19 | 0.21 | 2349.27 | 0.46 |
Construction land | 21,870.27 | 4.24 | 28,844.01 | 5.60 | 51,410.97 | 9.98 |
Cultivated land | 94,508.37 | 18.34 | 101,316.78 | 19.66 | 75,394.89 | 14.63 |
Total area (hm2) | 515,374.29 | 515,374.29 | 515,374.29 |
Land-Use Type | 2000–2010 (% Change) | 2010–2020 (% Change) | 2000–2020 (% Change) |
---|---|---|---|
Grassland | −2.458 | 0.054 | −1.209 |
Forest | −0.005 | 0.049 | 0.022 |
Water | −5.516 | 11.589 | −0.160 |
Construction land | 3.189 | 7.824 | 6.754 |
Cultivated land | 0.721 | −2.590 | −1.028 |
Overall dynamic | 0.266 | 0.505 | 0.304 |
2000 2020 | Grassland | Forest | Water | Construction Land | Cultivated Land | Total 2020 |
---|---|---|---|---|---|---|
Grassland | 30,191.94 | 3267.09 | 509.58 | 441.27 | 3450.15 | 37,860.03 |
Forest | 5375.07 | 335,275.02 | 114.3 | 87.12 | 7463.52 | 348,315.03 |
Water | 215.19 | 243.99 | 1415.43 | 99.45 | 376.38 | 2350.44 |
Construction land | 5243.22 | 6361.11 | 117.18 | 20,001.15 | 19,715.76 | 51,438.42 |
Cultivated land | 8888.13 | 1508.04 | 270.36 | 1241.28 | 63,502.56 | 75,410.37 |
Total 2000 | 49,913.55 | 346,655.25 | 2426.85 | 21,870.27 | 94,508.37 | 515,374.29 |
Landscape Index | Year | Grassland | Forest | Water | Construction Land | Cultivated Land |
---|---|---|---|---|---|---|
NP | 2000 | 19,721 | 4240 | 255 | 397 | 504 |
2010 | 21,217 | 4279 | 166 | 716 | 639 | |
2020 | 20,148 | 4032 | 99 | 833 | 1266 | |
PD | 2000 | 3.8265 | 0.8227 | 0.0495 | 0.077 | 0.0978 |
2010 | 4.1168 | 0.8303 | 0.0322 | 0.1389 | 0.124 | |
2020 | 3.9109 | 0.7827 | 0.0192 | 0.1617 | 0.2457 | |
LPI | 2000 | 0.4562 | 58.413 | 0.2188 | 0.4758 | 5.5887 |
2010 | 0.3469 | 58.350 | 0.0295 | 0.6134 | 7.7833 | |
2020 | 0.331 | 28.804 | 0.137 | 1.2581 | 6.7998 | |
AI | 2000 | 79.211 | 97.138 | 87.064 | 94.906 | 96.156 |
2010 | 74.1297 | 97.110 | 83.632 | 94.339 | 96.403 | |
2020 | 75.4517 | 97.142 | 90.704 | 94.919 | 94.778 |
Land-Use Type | 2000 SPLIT | 2010 SPLIT | 2020 SPLIT |
---|---|---|---|
Grassland | 8900.71 | 20,823.10 | 20,747.92 |
Forest | 2.91 | 2.92 | 6.15 |
Water | 197,097.68 | 4,145,895.14 | 409,223.17 |
Construction land | 16,916.41 | 9909.91 | 2720.01 |
Cultivated land | 197.68 | 101.39 | 204.30 |
Land-Use Type | Reality 2020 | PLUS Simulation Correct Number | Accuracy (%) | FLUS Simulation Correct Number | Accuracy (%) |
---|---|---|---|---|---|
Grassland | 37,865 | 25,844 | 68.25% | 24952 | 65.90% |
Forest | 348,365 | 331,697 | 95.22% | 331787 | 95.24% |
Water | 2338 | 1698 | 72.63% | 1681 | 71.90% |
Construction land | 51,427 | 26,453 | 51.44% | 25,900 | 50.36% |
Cultivated land | 75,389 | 68,287 | 90.57% | 68,358 | 90.67% |
Landscape Indices | Observed 2020 | PLUS | FLUS |
---|---|---|---|
NP | 7973 | 8463 | 8402 |
LPI | 57.64 | 59.15 | 59.12 |
PARA_MN | 320.29 | 331.41 | 333.67 |
PARA_AM | 45.55 | 44.24 | 43.72 |
PARA_MD | 400 | 400 | 400 |
PARA_RA | 380.54 | 379.57 | 380.54 |
PARA_SD | 99.93 | 90.45 | 89.29 |
PARA_CV | 31.2 | 27.29 | 26.76 |
ENN_MN | 342.06 | 327.27 | 326.37 |
ENN_AM | 225.53 | 216.69 | 214.14 |
ENN_MD | 223.61 | 223.61 | 223.61 |
ENN_RA | 15,599.05 | 15,466.84 | 15,466.84 |
ENN_SD | 467.65 | 447.15 | 446.76 |
ENN_CV | 136.71 | 136.63 | 136.89 |
PLADJ | 88.61 | 88.94 | 89.07 |
2020 2030 | Grassland | Forest | Water | Construction Land | Cultivated Land | Total 2030 |
---|---|---|---|---|---|---|
Grassland | 37,865 | 82 | 17 | 37,964 | ||
Forest | 348,177 | 348,177 | ||||
Water | 6 | 2338 | 683 | 3027 | ||
Construction land | 100 | 51,427 | 16,520 | 68,047 | ||
Cultivated land | 58,169 | 58,169 | ||||
Total 2020 | 37,865 | 348,365 | 2338 | 51,427 | 75,389 | 515,384 |
2020 2030 | Grassland | Forest | Water | Construction Land | Cultivated Land | Total 2030 |
---|---|---|---|---|---|---|
Grassland | 37,865 | 77 | 22 | 37,964 | ||
Forest | 348,177 | 348,177 | ||||
Water | 1 | 2338 | 688 | 3027 | ||
Construction land | 110 | 51,427 | 16,510 | 68,047 | ||
Cultivated land | 58,169 | 58,169 | ||||
Total 2020 | 37,865 | 348,365 | 2338 | 51,427 | 75,389 | 515,384 |
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Wang, J.; Zhang, J.; Xiong, N.; Liang, B.; Wang, Z.; Cressey, E.L. Spatial and Temporal Variation, Simulation and Prediction of Land Use in Ecological Conservation Area of Western Beijing. Remote Sens. 2022, 14, 1452. https://doi.org/10.3390/rs14061452
Wang J, Zhang J, Xiong N, Liang B, Wang Z, Cressey EL. Spatial and Temporal Variation, Simulation and Prediction of Land Use in Ecological Conservation Area of Western Beijing. Remote Sensing. 2022; 14(6):1452. https://doi.org/10.3390/rs14061452
Chicago/Turabian StyleWang, Jia, Junping Zhang, Nina Xiong, Boyi Liang, Zong Wang, and Elizabeth L. Cressey. 2022. "Spatial and Temporal Variation, Simulation and Prediction of Land Use in Ecological Conservation Area of Western Beijing" Remote Sensing 14, no. 6: 1452. https://doi.org/10.3390/rs14061452
APA StyleWang, J., Zhang, J., Xiong, N., Liang, B., Wang, Z., & Cressey, E. L. (2022). Spatial and Temporal Variation, Simulation and Prediction of Land Use in Ecological Conservation Area of Western Beijing. Remote Sensing, 14(6), 1452. https://doi.org/10.3390/rs14061452